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| United States Patent |
5,686,826
|
|
Kurtz
, et al.
|
November 11, 1997
|
Ambient temperature compensation for semiconductor transducer structures
Abstract
The present compensating circuit operates to reduce the span shift error
due to ambient temperature changes of a span resistance compensated,
bridge array circuit arrangement for a semiconductor transducer employing
piezoresistive sensors. The span resistance method alone cannot reduce the
span shift error to less than one percent (1%) for full scale. The present
compensating circuit applies a constant voltage source, derived from the
voltage source applied to the transducer, to a non-inverting input to an
operational amplifier. The circuit also applies an ambient temperature
dependent voltage, derived from the ambient temperature dependent bridge
resistance of the bridge array circuit, to an inverting input of the
operational amplifier. Both inputs to the operational amplifier are fed
back through a different resistance loop to control the output voltage in
response to the non-linearity of the ambient temperature dependent bridge
resistance. The present circuit produces a compensation voltage which
counteracts the downward span shift influence of the bridge resistance,
resulting in a span shift error of less than five tenths of a percent
(0.5%) for full scale.
| Inventors:
|
Kurtz; Anthony D. (Teaneck, NJ);
Landmann; Wolf S. (Leonia, NJ)
|
| Assignee:
|
Kulite Semiconductor Products (Leonia, NJ)
|
| Appl. No.:
|
617502 |
| Filed:
|
March 15, 1996 |
| Current U.S. Class: |
323/365; 330/146 |
| Intern'l Class: |
H03H 002/00; H03F 003/26 |
| Field of Search: |
323/365,367,368
73/721,727
330/146
|
References Cited
U.S. Patent Documents
| 3568044 | Mar., 1971 | Elazar | 323/365.
|
| 3651696 | Mar., 1972 | Rose | 323/365.
|
| 3831042 | Aug., 1974 | La Claire | 307/310.
|
| 4171509 | Oct., 1979 | Stephens et al. | 323/365.
|
| 4192005 | Mar., 1980 | Kurtz.
| |
| 4333349 | Jun., 1982 | Mallon et al.
| |
| 4419620 | Dec., 1983 | Kurtz et al. | 323/367.
|
| 4476726 | Oct., 1984 | Kurtz et al.
| |
| 4611163 | Sep., 1986 | Madeley | 323/367.
|
| 5053692 | Oct., 1991 | Craddock | 323/365.
|
| 5398194 | Mar., 1995 | Brosh et al.
| |
Primary Examiner: Wong; Peter S.
Assistant Examiner: Vu; Bao Q.
Attorney, Agent or Firm: Plevy & Associates
Claims
We claim:
1. In a pressure transducer apparatus containing one or more piezoresistive
elements formed by an integrated circuit technique arranged in a bridge
array on a force responsive member having a span resistance element
connected between a source of biasing potential and a terminal of said
bridge array and means for providing an additional voltage as a function
of temperature from a separate source and output terminals for providing a
transducer output voltage, said bridge array having an ambient temperature
dependent bridge resistance operative to influence a non-linear response
in said transducer output voltage, in combination therewith the
improvement comprising:
compensating means for producing a compensation voltage responsive to said
ambient temperature dependent resistance of said bridge array; and,
input means coupling said compensating means with said bridge array and
said span resistance element for counteracting said ambient temperature
dependent bridge resistance to linearize said non-linear response in said
transducer output voltage;
wherein said compensation means includes an amplifier, negative feedback
means and positive feedback means, said amplifier having an inverting
input terminal, a non-inverting input terminal, an output terminal, and an
operating bias from an independent source potential, said negative
feedback means having a first end coupled to said output terminal of said
amplifier and a second end coupled to said terminal of said bridge array
and said inverting input terminal of said amplifier, and said positive
feedback means having a first end coupled to said output terminal of said
amplifier and a second end coupled to said span resistance element and
said non-inverting input terminal of said amplifier.
2. The combination according to claim 1, wherein said compensation means
includes an amplifier having an inverting input terminal, a non-inverting
input terminal, an output terminal, and an operating bias from an
independent source potential, negative feedback means coupled at one
terminal to said output terminal and at the other terminal to said
inverting input terminal and between said span resistance and said bridge
array, and positive feedback means coupled at one terminal to said output
terminal and at the other terminal to said non-inverting input terminal
and said input means.
3. The combination of claim 1, wherein said input means includes means for
biasing said inverting input terminal with a constant source potential
derived from said source of biasing potential of said transducer
apparatus.
4. The combination according to claim 1, wherein said means for biasing of
said input means includes a voltage divider circuit with a first resistor
and a second resistor each having a first terminal connected together and
connected to said non-inverting input and said positive feedback, other
terminal of said first resistance connected between said span resistance
and said source of biasing potential, other terminal of said second
resistor connected to ground.
5. The combination according to claim 1, wherein said amplifier is an
operational amplifier.
6. The combination according to claim 1, wherein said positive feedback
means is a resistor.
7. The combination according to claim 1, wherein said negative feedback
means is a resistor.
8. An ambient temperature compensating apparatus for a transducer of the
type employing a conventional Wheatstone bridge array having first and
second input terminals for applying a source of biasing potential
therebetween and first and second output terminals for obtaining a
transducer output voltage therebetween and a span resistance connected
between said Wheatstone bridge array and a source of biasing potential,
said Wheatstone bridge array having an ambient temperature dependent
bridge resistance operative to influence an undesirable non-linear
response in said transducer output voltage, said ambient temperature
compensating apparatus operative to counteract said ambient temperature
dependent bridge resistance, comprising:
amplifier means for amplifying an ambient temperature dependant voltage
derived from said ambient temperature dependent resistance of said
Wheatstone bridge array to produce an amplifier voltage output;
positive feedback means coupled to said amplifier means for influencing
slope of said amplifier voltage output;
negative feedback means coupled to said amplifier means for influencing
when said amplifier voltage output is positive; and,
input means for applying said ambient temperature dependant voltage to said
amplifier means and coupling said amplifier voltage output to said
Wheatstone bridge array and said span resistance so as to counteract said
ambient temperature dependent bridge resistance, said input means coupling
said amplifier means with said Wheatstone bridge and said span resistance.
9. The apparatus of claim 8, wherein said amplifier means includes an
inverting input terminal, a non-inverting input terminal, an output
terminal, and an operating bias from an independent source potential.
10. The apparatus of claim 9, wherein said negative feedback means is
coupled at one terminal to said output terminal and at the other terminal
to said inverting input terminal and between said span resistance and said
bridge array.
11. The apparatus of claim 10, wherein said positive feedback means is
coupled at one terminal to said output terminal and at the other terminal
to said non-inverting input terminal and said input means, a potential
from said positive feedback means being greater than a potential from said
negative feedback means, said positive feedback means operative to
influence the slope of said amplifier output voltage.
12. The apparatus of claim 11, wherein said input means includes a voltage
divider circuit with a first resistor and a second resistor each having a
first terminal connected together and connected to said non-inverting
input and said positive feedback, other terminal of said first resistance
connected between said span resistance and said source of biasing
potential, other terminal of said second resistor connected to ground.
13. The apparatus of claim 12, wherein said amplifier means is an
operational amplifier.
14. The apparatus of claim 12, wherein said positive feedback means and
said negative feedback means each include a resistor.
15. A method for improving the span shift response of a transducer
employing the span resistor method of compensating for an ambient
temperature dependent bridge array circuit arrangement, comprising the
steps of:
deriving an ambient temperature dependent voltage from said bridge array
circuit arrangement;
applying said ambient temperature dependent voltage as an input to an
inverted input terminal of an amplifier to produce an amplifier voltage
output;
coupling a constant voltage source derived from said source potential
applied to said span resistance to a non-inverted input terminal of said
amplifier;
feeding back a portion of said amplifier voltage output to said
non-inverted input terminal of said amplifier through a positive feedback
loop;
feeding back a portion of said amplifier voltage output to said inverted
input terminal of said amplifier through a negative feedback loop;
producing a compensating voltage from said amplifier output voltage when a
potential said positive feedback loop is greater than a potential from
said negative feedback loop; and,
coupling said compensating voltage with said ambient temperature dependent
bridge array circuit arrangement for reducing said span shift response of
said transducer.
16. The method of claim 15, wherein said amplifier is an operational
amplifier with an operating bias from an independent source potential.
17. The method of claim 16, wherein said negative feedback loop is a
resistor coupled at one terminal to said output terminal and at the other
terminal to said inverting input terminal and between said span resistance
and said bridge array, said negative feedback loop operative to influence
when said amplifier output voltage becomes positive.
18. The method of claim 17, wherein said positive feedback loop is a
resistor coupled at one terminal to said output terminal and at the other
terminal to said non-inverting input terminal and said input means, said
positive feedback loop operative to influence the slope of said
compensation voltage.
19. The method of claim 18, wherein said step of coupling a constant
voltage source is with a voltage divider circuit with a first resistor and
a second resistor each having a first terminal connected together and
connected to said non-inverting input and said positive feedback, other
terminal of said first resistance connected between said span resistance
and said source of biasing potential and other terminal of said second
resistor connected to ground.
Description
FIELD OF THE INVENTION
This invention relates to integrated circuit semiconductor transducer
structures in general and more particularly to a circuit for reducing the
span shift of a transducer having a non-linear, ambient temperature
dependent response.
BACKGROUND OF THE INVENTION
The prior art discloses pressure measuring devices such as semiconductor
types which are fabricated from piezoresistive sensors integrally diffused
within a diaphragm of semiconducting material such as silicon. Such
devices are fabricated using solid state techniques which basically
involve the diffusion or deposition of a force sensitive arrangement of
piezoresistors on a semiconductor diaphragm. The integral silicon
transducers are conventionally formed in a four active arm Wheatstone
bridge configuration providing an output proportional to pressure and/or
deflection. The stress sensors or piezoresistors are typically arranged so
that two elements of the four are subjected to tension and two are
subjected to compression. This type of arrangement has been referred to in
the prior art as an integral or integrated transducer and the terminology
is used to denote the fact that the piezoresistive sensing elements are
actually deposited, diffused or otherwise formed on a semiconductor
substrate employing fabrication techniques used in integrated circuit
technology.
The transducer configuration as a half bridge array or a full Wheatstone
bridge array is widely employed and is an extremely typical arrangement.
As a result of the applied pressure, the output of the bridge, when
supplied with a constant direct current (DC) or alternating current (AC)
voltage, is proportional to the pressure.
It has long been known, however, that the output of such a bridge will
generally decrease with increasing temperature because of the basic
temperature variation of the piezoresistive coefficient of the
semiconductor. This is commonly referred to as the span or sensitivity
shift. By using degenerately doped semiconductors, the temperature
variation can be reduced from about 20% per 100.degree. F. in lightly
doped silicon to about 1% to 2% per 100.degree. F. in the degenerate case.
In order to obtain even less temperature variation in the output, various
compensation methods must be employed. These make use of the fact that the
temperature coefficient of resistance of the bridge elements are positive
and are greater in magnitude than the decrease with temperature of the
piezoresistive coefficient. Thus, if a resistor is connected in series
with the bridge and the resulting circuit is powered with a constant
voltage, the voltage across the bridge will increase as a function of
temperature and an output more independent of temperature will result.
Such a method is disclosed in U.S. Pat. No. 4,419,620, entitled
"Linearizing Circuits For A Semiconductor Pressure Transducer", issued to
Kurtz et al. As the temperature of the bridge is increased, its resistance
increases and more of the supply is dropped across the bridge. By proper
choice of the ratio of the series resistor (commonly referred to as a span
resistor) to the bridge resistance, the requisite increase in bridge
voltage with temperature required to compensate for the decrease in
piezoresistive coefficient may be obtained and bridge voltage output can
be made more independent of temperature. Additionally, a combination of
resistors in series with and or in parallel with the bridge can be used.
A major advantage of this compensation scheme is that the temperature
sensing element, the piezoresistive element, is the very element subjected
to the varying temperature, while the resistor or resistors used in the
compensation configuration are constant with temperature (fixed
resistors). As a result, the correction provided by this method is
practically instantaneous, and not subject to temperature gradients, time
constants, etc. However, a major shortcoming of this compensation method
is its inability to consistently improve the accuracy or reduce the span
shift to less than one percent (1%), even with the most degenerate
semiconductors over a large temperature excursion. Two limitations which
affect this accuracy are that the decrease in the piezoresistive
coefficient is not linear with temperature, increasing in absolute value
at high temperature, and the compensation itself is non-linear with
temperature due to the factor R.sub.BRIDGE /(R.sub.SPAN +R.sub.BRIDGE)
which itself is non-linear with temperature. Assuming R.sub.SPAN is
constant and R.sub.BRIDGE increases linearly with temperature, this
correction factor is decreasing with temperature, providing less
compensation exactly where more compensation is needed. As a result,
transducers compensated this way can achieve a close to perfect stability
of the output from extreme cold to about eighty degrees centigrade
(80.degree. C.), and about minus two percent to minus three percent (-2%
to -3%) error at elevated temperatures (125.degree. C. to 150.degree. C.).
One common method for overcoming such non-linearity uses a thermistor in
the circuit, usually across the span resistor. For that case the span
resistor is divided into two resistors and a thermistor with an additional
resistor used to shunt one of the span resistors. Moreover, this technique
defeats the main advantage of having the piezoresistive bridge itself as
the only temperature dependent component. In addition, it requires
considerable effort to tailor the new resistor-thermistor network to
obtain the correct non-linearity correction.
Accordingly, it is an object of the present invention to disclose a method
for improving the compensation for the non-linear, ambient temperature
dependent response of semiconductor transducers, in a rapid and efficient
manner.
SUMMARY OF THE INVENTION
The present invention is a circuit for improving the span resistance method
of compensating for an ambient temperature dependent, non-linear response
of a semiconductor transducer employing a bridge array circuit
arrangement. The transducer has input terminals connected to the span
resistance which in turn is connected to a voltage source and output
terminals for providing a transducer output voltage. The circuit for
improving the non-linear response includes an operational amplifier having
an inverting input terminal, a non-inverting input terminal, an output
terminal, and an operating bias from an independent source potential.
A negative feedback loop is coupled at one terminal to the output terminal
of the amplifier and at the other terminal to the inverting input terminal
of the amplifier and between the span resistance and the bridge array. A
positive feedback loop is coupled at one terminal to the output terminal
of the amplifier and at the other terminal to the non-inverting input
terminal and a biasing voltage divider circuit.
The biasing voltage dividing circuit which provides a constant voltage
source to the non-inverting input to the amplifier is derived from the
voltage supply to the bridge array through the span resistance. A first
resistor and a second resistor are connected together and connected to the
non-inverting input and the positive feedback loop. The other terminal of
the first resistance is connected between the span resistance and the
voltage supply, while the other terminal of the second resistor connected
to ground.
As the ambient temperature increases, the bridge resistance operates to
cause an increasing non-linear deviation or span shift downward from a
true linear response, in the method employing a lone span resistance which
is temperature independent, and the span shift cannot be reduced to less
than several percent (1%) of full scale over an extended temperature
range. The present invention provides a non-linear increase in the bridge
voltage which makes possible the compensation of the transducer circuit to
less than several tenths of a percent over the same temperature range. The
negative feedback loop to the amplifier operates to influence when the
amplifier output voltage from the amplifier becomes positive, thereby
providing a linearly increasing feedback voltage to the bridge once the
amplifier is positively biased. One set of resistors is used to set the
temperature at which the amplifier is positively biased and another set of
resistors is used to define the slope of the feedback voltage as a
function of temperature.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will be better understood with reference to the following
illustrative and non-limiting drawings, in which:
FIG. 1 is a circuit schematic of a known compensation method using a span
resistor to compensate for a non linear response induced by ambient
temperatures.
FIG. 2 is a partial circuit schematic of the present method for
compensating for ambient temperature.
FIG. 3 is a complete schematic of the present method for improving the
accuracy of a span resistance method for overcoming errors induced by
ambient temperature variations.
FIG. 4 is a graph comparing temperature compensation errors with and
without the present method.
FIG. 5 is graph of an amplifier output voltage versus changing ambient
temperature with under the present invention.
FIG. 6 is a practical implementation of a temperature compensating ciruit
showing the current buffer transistor Q.sub.1.
FIG. 7 shows a polynomial compensation circuit in accordance with the
present invention.
DETAILED DESCRIPTION OF THE INVENTION
Although the present invention can be used in different applications where
a temperature compensation is desirable, the present invention is
especially suited for improving the accuracy of piezoresistive type
pressure transducers employing a span resistor to compensate for an
ambient temperature dependant response. Accordingly, the present invention
will be described in conjunction with improving the accuracy of
piezoresistive type transducers using a span resistance to compensate for
ambient temperature induced errors.
A known technique of using a fixed resistor, known as a span resistor, to
reduce the temperature dependency of the span output of the transducer
fails to improve the accuracy to less than a few percent of full scale.
There is shown in FIG. 1, with like elements like numbered or designated in
all Figures, the known circuit for reducing the effect caused by ambient
temperature variations of a full Wheatstone bridge array 10. The bridge
array 10 includes resistors 11 and 12 on the compression sensitive arm and
resistors 13 and 14 on the tension arm. The supply voltage 18, designated
as V.sub.REF, for the bridge is generated by a voltage regulator so as to
remain constant with changing ambient temperatures. As noted above, the
optimal value of the span resistor 17 (R.sub.SP1) is determined by the
temperature coefficient of the resistance (TCR) and the temperature
coefficient of the gage factor (TCGF). This method requires that the TCGF,
in absolute value, to be smaller than the TCR.
The present method replaces the span resistor circuit of FIG. 1 with the
whole circuit shown in FIG. 2, which includes a parallel combination of
resistors 17 (R.sub.SP1) and 19 (R.sub.SP2) in which resistor 19
(R.sub.SP2) is "k" times larger than resistor 17 (R.sub.SP1). The purpose
of this circuit is to compensate the temperature dependency of the
transducer output in a manner similar to the single span resistor for
temperatures up to a certain point (corner temperature) and to provide an
additional increase of the bridge voltage past the corner temperature.
This mode of operation is accomplished by having the output of the
operational amplifier (V.sub.COMP-T) being zero (or constant) up to the
corner temperature and linearly increasing with temperature thereafter.
To understand the operation of the circuit it may be useful to reduce it to
the Thevenin equivalent. To do so the circuit is first reduced to the
circuit shown in FIG. 2. The Thevenin equivalent circuit is then in fact
identical to the circuit in FIG. 1 for temperatures less than the corner
temperatures. For temperatures in excess of this value the regulated
voltage V.sub.REF is not constant anymore but linearly increasing with
temperature, thereby providing the additional compensation required to
reduce the temperature dependency of the transducer's output.
To achieve the intended function, the circuit amplifies the temperature
dependent voltage at the junction between the pressure sensor and the span
resistor. Due to the offset provided by resistors R.sub.2 and R.sub.3, the
output of the amplifier should theoretically be negative for temperatures
less than the corner temperature. However, because the operational
amplifier is provided only with a positive supply voltage, the output is
clamped to zero (or a small saturation voltage) for temperatures less than
the corner temperature and linearly increasing thereafter. The corner
temperature is determined by the resistors R.sub.2 and R.sub.3, and the
slope of the temperature dependent voltage V.sub.COMP-T is determined by
R.sub.5.
Practical considerations may require addition of a transistor Q.sub.1, as
shown in FIG. 6, in order to increase the current drive capability of the
operational amplifier. The transistor Q.sub.1 is not required however, for
bridge resistances of about 2000 ohms (.OMEGA.) or more.
The performance of the circuit can be further enhanced by adding a second
amplifier stage, as shown in FIG. 7, with a second operational amplifier
A.sub.2 and resistors R.sub.6, R.sub.7, R.sub.8, and R.sub.9, thereby
generating a compensation made of three (3) linear segments: a constant or
zero compensation up to a first corner temperature, followed by a moderate
slope up to a second corner temperature and a subsequent higher slope for
temperatures in excess of the second corner temperature.
The increasing non-linear change provided by the compensation voltage 20
(V.sub.COMP-T) applied to resistor 19 (R.sub.SP2) in the circuit of FIG. 2
counteracts the decreasing non-linear change of the lone span resistor 17
(R.sub.SP1) in the circuit of FIG. 1. Referring now to the graph of FIG.
4, the curve labelled "initial span error" depicts the percent error for
the traditional SPAN resistor compensation method of FIG. 1 in a typical
transducer. The curve labelled "Non-lin compensation" shows the effect
induced by the compensation voltage 20 (V.sub.COMP-T) applied to the
parallel resistor 19 (R.sub.SP2). The combined effects of the increasing
compensation percent error induced by the compensation voltage 20
(V.sub.COMP-T) and the decreasing percent error for the traditional lone
span resistor results in the more linear response depicted by the curve
labelled (combined error), wherein the maximum percent error is less than
plus minus half a percent (.+-.0.5%).
The complete schematic of FIG. 3 shows how the advantage of the known
method of single span resistor of deriving the compensation voltage from
the changing resistance of the bridge versus ambient temperature, is
preserved in the proposed circuit. The operational amplifier 25 has an
inverting input (-) and a non-inverting input (+). Examples of suitable
operational amplifiers are well known in the art. Essentially, an
operational amplifier is a high gain device and many suitable amplifiers
are commercially available. The operating characteristics of such
amplifiers as 25 are well understood.
The amplifier 25 receives its supply voltage from the same source 18 as the
piezoresistive bridge. The amplifier 25 has its inverting input coupled to
the bridge 10 at terminal 28. Coupled to the inverting input of the
amplifier 25 and the bridge 10 at terminal 28 is resistor 22, designated
as R.sub.4 (k x span), which is connected at its other terminal to the
output of the amplifier 25. Coupled to the inverting input of the
amplifier 25, resistor 22, and terminal 28 of the bridge 10 is the span
resistor 17 which is connected at its other terminal to the supply voltage
18 (V.sub.REF). The amplifier has its non-inverting input coupled to
resistor 21, designated as R.sub.2 (corner), resistor 23, designated as
R.sub.5 (slope), and resistor 24, designated as R.sub.3. The other
terminal of resistor 21 is connected to the other terminal of resistor 17
and the supply voltage 18. The other terminal of resistor 23 is connected
to the output of the amplifier 25 and the other terminal of resistor 22.
The other terminal of resistor 24 is grounded. The full bridge array
elements being like numbered in FIG. 1 and FIG. 2 are the same elements
described above.
The notable advantage of the circuit in FIG. 3 stems from the compensation
voltage, discussed in conjunction with FIG. 2, being derived from the
changing resistance of the bridge 10 versus temperature, therefore
retaining the advantages of the traditional method. More specifically, the
circuit of FIG. 3 takes advantage of the temperature dependent voltage
across the bridge 10 between terminals 29 and 30, due to the typical ten
percent (10%) per fifty five degree centigrade (55.degree. C.) temperature
coefficient of the bridge 10 resistance. The voltage across terminals 29
and 30 is applied to the inverting input of the amplifier 25. The
non-inverting input is biased with a constant voltage derived from the
supply voltage 18 through resistors 21 (R2) and 24 (R3). Theoretically,
the output of the amplifier 25 varies with temperature from a negative
value at the extreme lower temperature to a positive value at the higher
temperature. Because the amplifier 25 is only supplied with a positive
voltage its output cannot be a negative voltage.
Referring now to FIG. 5 there is shown the actual voltage output of the
amplifier 25 as a function of changing ambient temperature. The graph is
based on the known dependency of the bridge resistance versus temperature,
one kilo-ohm at twenty five degrees centigrade (1 k.OMEGA. at 25.degree.
C.) with a temperature compensation ratio (TCR) of ten percent per 55
degrees centigrade (10% per 55.degree. C.). The corner temperature 31 is
adjusted to the optimum value by means of changing one of the resistors 21
(R.sub.2) or 24 (R.sub.3). The slope of the output for temperatures above
the corner temperature 31 is adjusted by means of the negative feedback
resistor 23 (R.sub.5, slope). It is noted that the circuit has a positive
feedback loop through resistor 22 (R.sub.4, kxSPAN). For stability the
negative feedback has to be less than the positive feedback. The formula
relating the output voltage to the value of the components in the circuit
is:
##EQU1##
It should be understood that the embodiment described herein is merely
exemplary and that a person skilled in the art may make many variations
and modifications to this embodiment utilizing functionally equivalent
elements to those described herein. Any and all such variations or
modifications as well as others which may become apparent to those skilled
in the art, are intended to be included within the scope of the invention
as defined by the appended claims.
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